KR100747120B1 - Heating system of boiler - Google Patents

Abstract

A heating system of a boiler is provided to minimize fuel consumption and improve heating efficiency by increasing the heat transfer area during operation of a heating member of the boiler such that the temperature of water flowing along a pipeline is maintained at a constant level. A heating system of a boiler(100) includes a main body(10), a heating member, a heat absorbing member, a heat exchange pipe(40), and a heat exchange unit(50). The main body includes a main pipe coupled with a circulation pump to circulate heating water, and an operating part(13). The heating member is arranged in the main body, and fitted to the heat absorbing member. The heat absorbing member absorbs heat generated during operation of the heating member. The heat exchange pipe is arranged in the heat absorbing member and filled with a heat exchange medium. The heat exchange pipe naturally circulates the heat exchange medium by heat absorbed by the heat absorbing member. The heat exchange pipe has an inlet(a1) and an outlet(a2) connected to the heat exchange unit. The main pipe of the main body passes through the heat exchange unit. The heat exchange unit heat-exchanges the heating water circulating through the main pipe to a predetermined temperature by the heat exchange medium naturally circulating through the heat exchange pipe.

Description

Heating system of boiler

1 is a perspective view of the structure of an electric boiler in an embodiment of the present invention.

Figure 2 is a plan view showing the structure of an electric boiler in an embodiment of the present invention.

3 is a combined state of the heat absorbing member and the heat exchange pipe in an embodiment of the present invention.

Figure 4 is a schematic cross-sectional view showing the structure of the electric boiler in an embodiment of the present invention.

Figure 5 is a schematic cross-sectional view showing the interior of the heat exchanger in the embodiment of the present invention.

Figure 6 is a schematic cross-sectional view showing the structure of a gas boiler in another embodiment of the present invention.

Figure 7 is a schematic cross-sectional view showing the structure of the oil boiler in another embodiment of the present invention.

* Description of the symbols for the main parts of the drawings *

10; Main body 11; Circulation pump

12a; Discharge line 12b; Return tube

13; Operation unit 14; Control

20; A heating member 30; Heat-absorbing member

31; Insulation 32; Joining hole

40; Heat exchange piping 41; Water supplement

42; Low water level sensor 50; Heat exchanger

51; Plate 60; Support frame

70; Temperature sensor 100; Electric boiler

100a; Hot water pipe 200; Gas boiler

201; Gas burner 300; Oil boiler

301; Oil burners 202, 302; frame

The present invention relates to a boiler, and more particularly, the heating element of the boiler increases the heat transfer area according to the heating during the heating operation so that the heating temperature of the medium (water) flowing through the boiler's heating and hot water pipes is always constant. It relates to a heating system of a boiler that can be maintained.

In general, boilers used for heating and hot water supply are constantly racing to get more calories, especially with less fuel, and will continue to be developed.

As is well known, boilers for heating and hot water are divided into electric boilers using electricity as a heat source, oil boilers using oil as a heat source, and gas boilers using gas as a heat source. Efforts to get more calories from fuels are constantly racing.

However, conventional boilers that use electricity, oil, and gas as heat sources directly heat the medium (water) through which heat transferred from the operation of heating elements (eg, heaters, oil / gas burners) circulates inside the pipe. While the heating cross-sectional area is small, it has the advantage of rapidly increasing the temperature of the medium to be purified in the pipe, while heating the heating element (heater, oil / gas burner) until all the medium in the pipe rises to a constant temperature. Inevitably, a lot of time is required, and this heating time is repeated, which causes a lot of fuel consumption problems.

In addition, heating elements (heaters, oil / gas burners) applied to conventional boilers have a disadvantage of causing complaints of consumers while inducing severe noise from the heating operation.

Accordingly, the present invention has been made to solve the above-mentioned conventional problems, and absorbs the heat generated during heating of the heating member to increase the heat transfer area according to the heating of the heating member (heater, oil / gas burner). After the box-shaped heat absorbing member is formed, the heat-absorbing member is constantly circulated in the heat-exchanging pipe in a state in which the heat-absorbing pipe is filled with a medium that maintains a constant temperature (about 90 ° C) by the heat absorbed. The purpose is to minimize the fuel consumption of the boiler by constructing a heating system that raises the temperature of the medium flowing along the piping of heating or hot water due to the medium of temperature.

In addition, another object of the present invention is to provide an electric boiler to which a dry heater is applied, and to improve the noise problem of the electric boiler to immerse the wet heater in the pipe so that the medium is heated in the pipe.

The heating system of the boiler of the present invention for achieving the above object, the main pipe portion is arranged to circulate the heating water is coupled to the circulation pump, the main body having an operation unit; A heating member configured in the main body; A heat absorbing member absorbing heat generated during a heating operation of the heating member; A heat exchange pipe part filled with a heat exchange medium and configured to naturally circulate the heat exchange medium when it is heated by heat absorbed by the heat absorbing member; And a heat exchanger configured to heat-exchange the heating water circulated along the main pipe through a heat exchange medium naturally circulated along the heat exchange pipe to a predetermined temperature. It includes.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings.

1 is a perspective view showing the structure of an electric boiler according to an embodiment of the present invention, Figure 2 is a plan view showing the structure of an electric boiler in an embodiment of the present invention, Figure 3 is a heat absorbing member and heat exchange pipe in an embodiment of the present invention Negative coupling is also

Figure 4 is a schematic cross-sectional view showing the structure of the electric boiler in an embodiment of the present invention, Figure 5 is a schematic cross-sectional view showing the inside of the heat exchanger in an embodiment of the present invention.

1 to 5, the heating system of the boiler according to the embodiment of the present invention includes a main body 10, a heating member 20, a heat absorbing member 30, a heat exchange pipe part 40, and a heat exchange part ( 50).

The main body 10 is arranged in the upper side of the main pipe for heating water circulation connected to the heat exchange unit 50, the main pipe portion discharge pipe 12a and the return pipe to receive the heating water through a separate supplementary line It is divided into (12b), the discharge pipe 12a is configured with a circulation pump (11).

At this time, the front of the main body 10 is composed of an operating unit 13 including a display unit 13a for displaying the temperature according to the operation of the boiler and the heating temperature of the heat exchange medium, as well as the boiler system in the operating unit 13 The control unit 14 for controlling the overall operation of the is configured.

The control unit 14 has an internal memory configured to store the limit temperature value of the maximum rise with respect to the heat exchange medium in the heat exchange pipe unit 40. The control unit 14 stores an internal memory in which the heating temperature of the heat exchange medium is stored in the internal memory. The circulation pump 11 and the heating member 20 are turned on until the maximum rising limit temperature (about 90 ° C.) is reached. When the maximum rising limit temperature is exceeded, the circulation pump 11 and the heating member 20 are turned on. The program for controlling off is configured.

The heating member 20 is located below the main body 10, which uses a dry heater or a gas burner or an oil burner according to the type of boiler. If the boiler of the present invention is an electric boiler, a dry heater, gas If the boiler is a gas burner, the oil boiler is configured to use an oil burner, in the present invention will be described with respect to the electric boiler.

The heating member 20 made of the dry heater is a rod-shaped heater unit, and is electrically connected to a substrate formed in the operation unit 13 and is controlled by the control unit 13. ) Is combined by fitting.

The heat absorbing member 30 is manufactured by a casting method, and the heat absorbing member 30 is configured to be recessed therein, and absorbs heat generated during the heating operation of the heating member 20. After that it is configured to transfer the heat exchange pipe 40.

At this time, the heat absorbing member 30 is supported by a separate support frame 60 in the main body 10, the aluminum having a high thermal conductivity to absorb the heat generated from the heating member 20 as described above Although (Al) is cast, all metal materials that provide thermal conductivity can be used.

In addition, the heat absorbing member 30 is configured to be insulated through a separate heat insulating material 31 so as to prevent the loss of the absorbed heat when absorbing heat, one side of the heating member 20 made of the dry heater A plurality of coupling holes 32 are configured to couple a plurality of).

The heat exchange pipe part 40 is formed in the heat absorbing member 30, and the inlet side (a1) and the outlet side (a2) at both ends thereof are connected to the heat exchange unit 50 to form a closed loop therein. Is filled with a heat exchange medium.

At this time, the heat exchange medium is preheated by the heat absorbed by the heat absorbing member 30, the natural circulation is made by the pressure rise in the heat exchange pipe portion 40 according to the preheating, the heat exchange pipe portion 40 Accordingly, heat exchange of the heating water is performed in the heat exchange part 50 by a heat exchange medium circulating naturally.

Here, the heat exchange pipe portion 40 is a portion except for the inlet side (a1) and the outlet side (a2) is formed in the coil shape in which the natural circulation of the heat exchange medium is formed in the heat absorbing member 30, the inlet The coil part, as well as the side (a1) and the inlet side (a1), are all made of stainless material to prevent corrosion.

In addition, the inlet side (a1) which is one side of the heat exchange pipe portion 40 is attached to the temperature sensor 70 for measuring the temperature of the heat-circulating medium that is naturally circulating, as well as the water supplement pipe 41 is configured, The low water level sensor 42 is attached to the water supplement pipe 41.

That is, the low water level sensor 42 detects when the water level of the water supplement pipe 41 is low and transmits it to the controller 14. Accordingly, the controller 14 circulates when the water supplement pipe 41 is at a low water level. By controlling the operation of the pump 11 and the heating member 20 to prevent overheating.

In addition, the temperature sensor 70 detects the temperature of the heat exchange medium returned to the heat exchange unit 50 from the inlet side a1 of the heat exchange pipe unit 40 and notifies the control unit 14 of the temperature of the heat exchange medium. 14) continuously operates the circulation pump 11 and the heating member 20 until the temperature of the heat exchange medium notified by the temperature sensor 70 reaches the limit temperature of the maximum rise, and the temperature of the heat exchange medium is maximum. When the limit temperature of the rise is exceeded, the operation of the circulation pump 11 and the heating member 20 is turned off.

The heat exchange part 50 is the heating water discharged through the discharge pipe 12a of the main pipe portion through a heat exchange medium naturally circulated along the heat exchange pipe portion 40 to the heat exchange portion 50 through the return pipe 12b. Upon return, the heating water is heat-exchanged to a predetermined temperature set as a heat-exchange medium flowing through the heat-exchanging pipe part 40, which is composed of a plurality of plate bodies 51 overlapping each other to form a flow path (not shown). The plurality of plate bodies 51 penetrate the main pipe portion for heating.

That is, when the heat exchange medium flows along the flow path formed between the plurality of plate bodies 51, the heating water in the main pipe part is preheated from the flow of the heat exchange medium.

The operation of the embodiment of the present invention configured as described above will be described with reference to FIGS. 1 to 5.

First, when the main power is supplied to the boiler, the control unit 14 configured in the main body 10 of the boiler turns on the operation of the circulation pump 11 and the heating member 20.

Then, the heating water is heated from the operation of the circulation pump 11 through the discharge pipe 12a of the main pipe portion, and forced circulation is performed to the return pipe 12b.

At this time, the operation of the heating member 20 at the same time, the heat generated from the heating member 20 is transferred to the heat absorbing member 30 having a large absorption cross-sectional area is absorbed,

After the heat absorption member 30 is formed in a coil shape, the heat absorption pipe part 40 having the inlet side a1 and the outlet side a2 at both ends thereof connected to the heat exchange unit 50 includes: Heat absorbed from the member 30 is transferred.

Then, the pressure in the heat exchange pipe portion 40 is increased, and accordingly, the heat exchange medium filled in the heat exchange pipe portion 40 is drawn in by the internal pressure rising as described above → the heat exchange portion 50. A natural circulation is performed in the direction of the flow path → the extraction side (a2) → the coil-shaped portion → the introduction side (a1) of the heat exchange pipe portion 40, and the temperature is increased.

At this time, the inlet side (a1) of the heat exchange pipe portion 40 is a water supplement pipe 41 is provided with a temperature sensor 70, and the low water level sensor 42,

The temperature sensor 70 checks the temperature rise of the heat exchange medium in which natural circulation occurs in real time, and transmits it to the controller 14.

Then, the controller 14 sets the maximum rise limit temperature of the heat exchange medium that can be adjusted in the memory therein, so that the temperature of the heat exchange medium checked by the temperature sensor 70 reaches the maximum rise limit temperature. Until the operation of the heating member 20 is controlled on.

Therefore, the heat absorbing member 30 absorbs heat generated from the heating operation of the heating member 20 as described above, and then transfers the heat absorbing member 30 to the coil-shaped heat exchange pipe unit 40 so as to absorb the heat. The temperature rise of the heat exchange medium flowing through the flow path (not shown) of the heat exchange part 50 including the 40 and the plurality of plate bodies 51 is led.

Then, when the heat exchange medium flows along the flow path in the heat exchange part 50, the heating water in the main pipe part passing through the plate body 51 of the heat exchange part 50 is controlled by the temperature of the heat exchange medium flowing along the flow path. The heat exchange is made to increase the temperature, and accordingly, the heating water discharged through the discharge pipe 12a and returned to the heat exchanger 50 through the return pipe 12b can always maintain a constant heating temperature.

Here, when the temperature of the heat exchange medium flowing to the inlet side (a1) of the heat exchange pipe portion 40 by the temperature sensor 70 exceeds the maximum rise limit temperature, the control unit 14 is the temperature sensor 70 On the basis of the information detected by the heating member 20, of course, by controlling the operation of the circulation pump 11, the heating is made to the elevated temperature for a predetermined time.

That is, in the present invention, when the heating member 20 is heated, heat generated in the heating member 20 is absorbed by the heat absorbing member 30 having a large cross-sectional area protected by the heat insulating material 31, and then the heat exchange pipe part. Bar indirectly heating the heat exchange medium in (40),

It takes some time until the temperature rise with respect to the initial heat absorbing member 30, but once the heat absorbing amount of the heat absorbing member 30 reaches the maximum, the heat absorbing without the heating operation of the heating member 20 Since the heating of the heat exchange medium in the heat exchange pipe part 40 is continuously performed from the discharge amount of heat absorbed by the member 30, the heating water heat exchange efficiency in the heat exchange part 50 is increased.

Here, the heat exchange medium filled into the heat exchange pipe part 40 is to be replenished through the water supplement pipe 41 formed on the inlet side (a1) of the heat exchange pipe part 40, if the replenishment is properly If the low water level is detected by the low water level sensor 42, the control unit 14 turns off the operation of the circulation pump 11 and the heating member 20 until the heat exchange medium is replenished from the low water level detection. To control.

Here, in the electric boiler 100 according to the embodiment of the present invention as shown in Figure 5, the heat exchange unit 50 may be configured as a hot water pipe 100a for hot water supply, as well as the main piping for heating. Accordingly, the hot water flowing along the inside of the hot water pipe 100a may be heat-exchanged in the heat exchange part 50 and then rise to a predetermined temperature to supply the water to the tap water.

On the other hand, in the embodiment of the present invention for the heating system of the boiler has been described for the electric boiler, the heating system as described above also in the gas boiler 200 and the oil boiler 200 as shown in Figs. The application is possible, and for this purpose, the gas burner 201 and the oil burner 301 which are heat sources of the gas boiler 200 and the oil boiler 300 are positioned at the lowermost side of the boiler body, and the gas burner 201 And a heat absorbing member 30 having a casting shape in which a heat exchange pipe part 40 is embedded on the upper side of the oil burner 301, and the heat exchange pipe part on the upper side of the gas and oil boilers 200 and 300. The inlet side a1 and the outlet side a2 of the 40, and the heat exchange part 50 to which the discharge pipe 12a and the return pipe 12b of the main piping part are connected.

In addition, between the gas and oil burners 201 and 301 and the heat absorbing member 30, frames 202 and 302 which prevent flames from spreading will be constructed.

Then, the effects of the electric boiler mentioned in the embodiment of the present invention can be obtained in the gas and oil boilers in the same manner.

As described above, the present invention allows the heating element of the boiler to maintain a constant heating temperature of the medium (water) flowing through the heating and hot water pipes of the boiler by increasing the heat transfer area according to the heating during the heating operation. In addition, the heating efficiency is maximized while minimizing the fuel consumption of the boiler, and the noise problem of the electric boiler using the wet heater can be obtained.

The present invention is not limited to the above-described specific preferred embodiments, and various modifications can be made by any person having ordinary skill in the art without departing from the gist of the present invention claimed in the claims. Of course, such changes will fall within the scope of the claims.

Claims (18)

A main pipe unit to which the circulation pump is coupled to circulate the heating water, the main body having an operation unit; A heating member configured in the main body; A heat absorbing member coupled to the heating member in a fitting manner and absorbing heat generated during a heating operation of the heating member; A heat exchange pipe part configured in the heat absorbing member to fill a heat exchange medium, and naturally circulating the heat exchange medium by heat absorbed by the heat absorbing member; And, A predetermined temperature is set in which the inlet side and the outlet side of the heat exchange pipe part are connected to each other, as well as through the main pipe part, and the heating water circulated along the main pipe part through a heat exchange medium circulating naturally along the heat exchange pipe part. Heat exchanger for heat exchange with a furnace; Boiler heating system, characterized in that comprising a. The heating system of a boiler according to claim 1, wherein the heat absorbing member is made of metal having high thermal conductivity. The heating system of a boiler according to claim 2, wherein the heat absorbing member is formed by a casting method. The heating system of claim 3, wherein the heat absorbing member is configured to be surrounded by a heat insulating material. The heating system of claim 4, wherein the heat absorbing member comprises a plurality of coupling holes to which a heating member made of a dry heater is coupled. The heating system of a boiler according to claim 1, wherein a supporting frame for fixing a heat absorbing member in a casting form is formed inside the main body. The heating system of claim 1, wherein both ends of the heat exchange pipe part are connected to the heat exchange part in a state configured in the heat absorbing member and configured as a closed loop. The heating system of the boiler according to claim 7, wherein the heat exchange pipe part is configured in the form of a coil in the heat absorbing member. The heating system of claim 8, wherein the heat exchange pipe part is made of stainless material to prevent corrosion. The heating system of claim 1, wherein a water supply pipe is disposed at one side of the heat exchange pipe part connected to the heat exchanger, and a low water level sensor is attached to the water supply pipe. The heating system of claim 1, wherein a temperature sensor for measuring a temperature of a heat-circulating medium that is naturally circulated is attached to one end of the heat exchange pipe that is exposed to the outside from the heat absorbing member and connected to the heat exchange unit. According to claim 1, wherein the main body is provided with a control unit is set the program for controlling the operation of the boiler from the operation of the operation unit, The control unit has a heating system of the boiler, characterized in that the internal memory for storing the limit temperature value of the maximum rise with respect to the heat exchange medium in the heat exchange pipe unit is configured to store it. The method of claim 12, wherein the control unit turns on the circulating pump and the heating member until the heating temperature of the heat exchange medium reaches the maximum rise limit temperature of the heat exchange medium stored in the internal memory, and when the maximum rise limit temperature is exceeded, A heating system of a boiler, characterized in that configured to control off the heating element. The heating system of claim 13, wherein the controller is configured to control off the circulation pump and the heating member when the low water level sensor is detected from the low water level sensor. 13. The heating system of a boiler according to claim 12, wherein the operation unit includes a display unit for displaying a temperature of the heat exchange medium measured by a temperature sensor. The heating system of a boiler according to claim 1, wherein the heat exchange part comprises a heating main pipe part and a hot water pipe at the same time. A gas boiler using a gas burner as a heating member, comprising a component of any one of claims 1 to 16, and a heat absorbing member having a heat sink pipe portion recessed while being formed in a corrugated shape on an upper side of the gas burner. And a frame for preventing flame spread in the space between the heat absorbing member and the gas burner. An oil boiler using an oil burner as a heating member, the heat absorbing member including the component of any one of claims 1 to 16, wherein the heat absorbing member is recessed on the upper side of the oil burner in a corrugated shape. And a frame for preventing flame spreading in a space between the heat absorbing member and the oil burner.

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